Delayed radio resource signaling in a mobile radio network

ABSTRACT

An implementation of a system, device and method for communicating location data of a mobile station, enhancing location data, optimally communicating Assistance Data, and/or reducing rebids of Measure Position Request messages in a wireless network.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §119(e) to: provisionalU.S. Patent Application 60/971,453, titled “GSM Control PlanePositioning Preemption RRLP Implementation for MS and SMLC”, filed onSep. 11, 2007; and provisional U.S. Patent Application 61/012,039,titled “GSM Control Plane Positioning Preemption RRLP Implementation forMS and SMLC”, filed on Dec. 6, 2007, the disclosures of which areexpressly incorporated by reference herein in their entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to communication systems, andmore particularly, to enhance position location using a globalnavigation satellite system.

2. Background of the Invention

It is often desirable, and sometimes necessary, to know the location ofa mobile station, (e.g., a cellular phone). The terms “location” and“position” are synonymous and are used interchangeably herein. Forexample, a user may utilize a mobile station (MS) to browse through awebsite and may click on location sensitive content. The location of themobile station may then be determined and used to provide appropriatecontent to the user. There are many other scenarios in which knowledgeof the location of the mobile station is useful or necessary. Forexample, the FCC's 911 mandate requires carriers to provide enhanced 911services including geographically locating a mobile station making a 911emergency services call. The mobile station may be provisioned such thatit can obtain location services from a home network and also whileroaming in a visited network. The mobile station may communicate withvarious network entities in the home network in order to determine thelocation of the mobile station whenever needed.

There are many different types of technologies employed in calculatingthe location of mobile stations in wireless networks with various levelsof success and accuracy. Network based methods include angle of arrival(AOA) using at least two towers, time difference of arrival (TDOA) usingmultilateration, and location signature using RF fingerprinting to matchRF patterns that mobile stations exhibit at known locations. Variousmobile station based methods incorporate GPS, Advanced Forward LinkTrilateration (A-FLT), Timing Advance/Network Measurement Report(TA/NMR) and/or Enhanced Observed Time Difference (E-OTD).

Another mobile station based method is assisted-GPS (A-GPS), in which aserver provides Assistance Data to the mobile station in order for it tohave a low Time to First Fix (TTFF), to permit weak signal acquisition,and to optimize mobile station battery use. A-GPS is used as a locationtechnology in isolation or hybridized with other positioningtechnologies that provide range-like measurements. An A-GPS serverprovides data to a wireless mobile station that is specific to theapproximate location of a mobile station. The Assistance Data helps themobile station lock onto satellites quickly, and potentially allows thehandset to lock onto weak signals. The mobile station then performs theposition calculation or optionally returns the measured code phases tothe server to do the calculation. The A-GPS server can make use ofadditional information such as round-trip timing measurements from acellular base station to the mobile station in order to calculate alocation where it may otherwise not be possible; for example when thereare not enough GPS satellites visible.

Advances in satellite-based global positioning system (GPS), timingadvance (TA), and terrestrial-based Enhanced Observed Time Difference(E-OTD) position fixing technologies enable a precise determination ofthe geographic position (e.g., latitude and longitude) of a mobilestation. As geographic location services are deployed within wirelesscommunications networks, such positional information may be stored innetwork elements and delivered to nodes in the network using signalingmessages. Such information may be stored in a Serving Mobile LocationCenter (SMLC), a Stand-Alone SMLC (SAS), a Position Determining Entity(PDE), a Secure User Plane Location Platform (SLP) and special purposemobile subscriber location databases.

One example of a special purpose mobile subscriber location database isthe SMLC proposed by the 3rd Generation Partnership Project (3GPP). Inparticular, 3GPP has defined a signaling protocol for communicatingmobile subscriber positional information to and from an SMLC. Thissignaling protocol is referred to as the Radio Resource LCS (LocationServices) protocol, denoted RRLP, and defines signaling messagescommunicated between a mobile station and an SMLC related to a mobilesubscriber's location. A detailed description of the RRLP protocol isfound in 3GPP TS 44.031 v7.9.0 (2008-06) 3rd Generation PartnershipProject; Technical Specification Group GSM Edge Radio Access Network;Location Services (LCS); Mobile Station (MS)-Serving Mobile LocationCenter (SMLC) Radio Resource LCS Protocol (RRLP) (Release 7).

In addition to the United States Global Positioning System (GPS), otherSatellite Positioning Systems (SPS), such as the Russian GLONASS systemor the proposed European Galileo System may also be used for positionlocation of a mobile station. However, each of the systems operatesaccording to different specifications.

One weakness of a satellite based position location system is the timetaken to acquire an accurate position fix. Typically, position accuracyis traded off for acquisition speed and visa versa. That is, a moreaccurate fix takes more time. Accordingly, there is a need for acommunication system, including a global navigation satellite system(GNSS), which can determine a position location for a mobile stationbased on satellite signals sent from two or more satellites to providefurther efficiencies and advantages for position location includingenhanced accuracy. A need exists to enhance accuracy while notdetrimentally impacting the acquisition speed or a final acquisitiontime of acquiring a position fix of a mobile station, for example,during an emergency services (ES) call or value added services (VAS)session.

SUMMARY

Some embodiments of the present invention provide for a method ofreducing rebids of Measure Position Request messages between a networkand a mobile station in a wireless network, the method comprising:transmitting an RRLP Assistance Data message; receiving an RRLPAssistance Data Ack message; waiting until a predetermined time, whereinthe predetermined time is based on a time location data is needed;transmitting, at the predetermined time, RRLP Measure Position Requestmessage comprising a network response time and a network accuracy,wherein the network response time comprises a value representing ashortened response time of not greater than 4 seconds, wherein thenetwork accuracy comprises a value representing low accuracy of not lessthan 100 meters, and wherein the RRLP Measure Position Request messagecomprises no Assistance Data; and receiving, at a time before thelocation data is needed, a RRLP Measure Position Response messagecomprising the location data.

Some embodiments of the present invention provide for a network forreducing rebids of Measure Position Request messages between the networkand a mobile station in a wireless network, the method comprising: atimer to wait until a predetermined time, wherein the predetermined timeis based on a time location data is needed; a transmitter to transmit,at the predetermined time, Measure Position Request message comprising anetwork response time and a network accuracy; and a receiver to receive,at a time before the location data is needed, a Measure PositionResponse message comprising the location data. The network wherein thenetwork response time comprises a value representing a shortenedresponse time of not more than 4 seconds. The network wherein thenetwork accuracy comprises a value representing low accuracy of not lessthan 100 meters. The network wherein the Measure Position Requestcomprises no Assistance Data. The network wherein the Measure PositionRequest message comprises an RRLP Measure Position Request message. Thenetwork wherein the Measure Position Response message comprises an RRLPMeasure Position Response message.

Some embodiments of the present invention provide for acomputer-readable product comprising a computer-readable mediumcomprising: code for causing at least one computer to wait until apredetermined time, wherein the predetermined time is based on a timelocation data is needed; code for causing at least one computer totransmit, at the predetermined time, Measure Position Request messagecomprising a network response time and a network accuracy; and code forcausing at least one computer to receive, at a time before the locationdata is needed, a Measure Position Response message comprising thelocation data. The computer-readable product wherein the networkresponse time comprises a value representing a shortened response timenot greater than 4 seconds. The computer-readable product wherein thenetwork accuracy comprises a value representing low accuracy not lessthan 100 meters. The computer-readable product wherein the MeasurePosition Request comprises no Assistance Data. The computer-readableproduct wherein the computer-readable medium comprising furthercomprises: code for causing at least one computer to transmit anAssistance Data message; and code for causing at least one computer toreceive an Assistance Data Ack message. The computer-readable productwherein the Measure Position Request message comprises an RRLP MeasurePosition Request message. The computer-readable product wherein theMeasure Position Response message comprises an RRLP Measure PositionResponse message.

Some embodiments of the present invention provide for a method, in anetwork, for minimizing rebids between the network and a mobile stationin a wireless network, the method comprising: sending a Request messagethereby opening a session in the mobile station; determining, while thesession is open, an RR message is ready to be sent to the mobilestation; avoiding aborting the session with the RR message; andreceiving a Response message thereby closing the session. The methodwherein the act of avoiding aborting the session comprises: waiting tosend the RR message; and sending the RR message after the session isclosed. The method wherein the act of avoiding aborting the sessioncomprises dropping the RR message. The method wherein the Requestmessage comprises an RRLP Measure Position Request message. The methodwherein the Request message comprises an RRLP Assistance Data message.

Some embodiments of the present invention provide for a network forminimizing rebids between the network and a mobile station in a wirelessnetwork, the network comprising: means for sending a Request messagethereby opening a session in the mobile station; means for determining,while the session is open, an RR message is ready to be sent to themobile station; means for avoiding aborting the session with the RRmessage; and means for receiving a Response message thereby closing thesession. The method wherein the means for avoiding aborting the sessioncomprises: means for waiting to send the RR message; and means forsending the RR message after the session is closed. The method whereinthe means for avoiding aborting the session comprises dropping the RRmessage. The method wherein the Request message comprises an RRLPMeasure Position Request message. The method wherein the Request messagecomprises an RRLP Assistance Data message.

Some embodiments of the present invention provide for a network forminimizing rebids between the network and a mobile station in a wirelessnetwork, the network comprising: a transmitter to send a Request messagethereby opening a session in the mobile station; logic to determine,while the session is open, an RR message is ready to be sent to themobile station; logic to avoid aborting the session with the RR message;and a receiver to receive a Response message thereby closing thesession. The network wherein the logic to avoid aborting the sessioncomprises: a timer to wait to send the RR message; wherein thetransmitter is further to send the RR message after the session isclosed. The network wherein the logic to avoid aborting the sessioncomprises logic to drop the RR message. The method wherein the Requestmessage comprises an RRLP Measure Position Request message. The methodwherein the Request message comprises an RRLP Assistance Data message.

Some embodiments of the present invention provide for acomputer-readable product comprising a computer-readable mediumcomprising: code for causing at least one computer to send a Requestmessage thereby opening a session in the mobile station; code forcausing at least one computer to determining, while the session is open,an RR message is ready to be sent to the mobile station; code forcausing at least one computer to avoid aborting the session with the RRmessage; and code for causing at least one computer to receive aResponse message thereby closing the session. The method wherein thecode for causing at least one computer to avoid aborting the sessioncomprises: code for causing at least one computer to wait to send the RRmessage; and code for causing at least one computer to send the RRmessage after the session is closed. The method wherein the code forcausing at least one computer to avoid aborting the session comprisescode for causing at least one computer to drop the RR message. Themethod wherein the Request message comprises an RRLP Measure PositionRequest message. The method wherein the Request message comprises anRRLP Assistance Data message.

These and other aspects, features and advantages of the invention willbe apparent from reference to the embodiments described hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be described, by way of example only,with reference to the drawings.

FIGS. 1A, 1B and 1C show various components and interfaces in a wirelessnetwork.

FIG. 2 shows a message flow diagram of a typical position locationprocess using RRLP sessions.

FIG. 3 shows pseudo segmentation of Assistance Data.

FIGS. 4 and 5 illustrate halting position determination based on a MSreceiving an extra RR message.

FIGS. 6 and 7 show events that start and shutdown a GPS engine, inaccordance with embodiments of the present invention.

FIG. 8 shows a message flow diagram highlighting early locationdetermination, in accordance with embodiments of the present invention.

FIGS. 9 and 10 illustrate a method of continuing position determinationafter an extra RR message is received, in accordance with embodiments ofthe present invention.

FIGS. 11 and 12 illustrate a method of optimally ordering downloadedAssistance Data, in accordance with embodiments of the presentinvention.

FIGS. 13 and 14 show a method of sending just-in-time position requests,in accordance with embodiments of the present invention.

FIGS. 15 and 16 show a method of delaying (or dropping) new RR messagesto avoid aborted sessions, in accordance with embodiments of the presentinvention.

FIGS. 17, 18, 19, 20 and 21 illustrate a method of varying an accuracyparameter to balance response time and accuracy in an emergency services(ES) call, in accordance with embodiments of the present invention.

FIG. 22 shows a message flow diagram for a value added service (VAS), inaccordance with embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In the following description, reference is made to the accompanyingdrawings, which illustrate several embodiments of the present invention.It is understood that other embodiments may be utilized and mechanical,compositional, structural, electrical, and operational changes may bemade without departing from the spirit and scope of the presentdisclosure. The following detailed description is not to be taken in alimiting sense. Furthermore, some portions of the detailed descriptionthat follows are presented in terms of procedures, steps, logic blocks,processing, and other symbolic representations of operations on databits that can be performed in electronic circuitry or on computermemory.

A procedure, computer executed step, logic block, process, etc., areconceived here to be a self-consistent sequence of steps or instructionsleading to a desired result. The steps are those utilizing physicalmanipulations of physical quantities. These quantities can take the formof electrical, magnetic, or radio signals capable of being stored,transferred, combined, compared, and otherwise manipulated in electroniccircuitry or in a computer system. These signals may be referred to attimes as bits, values, elements, symbols, characters, terms, numbers, orthe like. Each step may be performed by hardware, software, firmware, orcombinations thereof. In a hardware implementation, for example, aprocessing unit may be implemented within one or more applicationspecific integrated circuits (ASICs), digital signal processors (DSPs),digital signal processing devices (DSPs), programmable logic devices(PLDs), field programmable gate arrays (FPGAs), processors, controllers,micro-controllers, microprocessors, electronic devices, other devicesunits designed to perform the functions described herein, and/orcombinations thereof.

Throughout this specification, reference may be made to “one example”,“one feature”, “an example” or “a feature” means that a particularfeature, structure, or characteristic described in connection with thefeature and/or example is included in at least one feature and/orexample of claimed subject matter. Thus, the appearances of the phrase“in one example”, “an example”, “in one feature” or “a feature” invarious places throughout this specification are not necessarily allreferring to the same feature and/or example. Furthermore, theparticular features, structures, or characteristics may be combined inone or more examples and/or features.

“Instructions” as referred to herein relate to expressions whichrepresent one or more logical operations. For example, instructions maybe “machine-readable” by being interpretable by a machine for executingone or more operations on one or more data objects. However, this ismerely an example of instructions and claimed subject matter is notlimited in this respect. In another example, instructions as referred toherein may relate to encoded commands which are executable by aprocessing circuit having a command set which includes the encodedcommands. Such an instruction may be encoded in the form of a machinelanguage understood by the processing circuit. Again, these are merelyexamples of an instruction and claimed subject matter is not limited inthis respect.

“Storage medium” as referred to herein relates to physical media capableof maintaining expressions which are perceivable by one or moremachines. For example, a storage medium may comprise one or more storagedevices for storing machine-readable instructions and/or information.Such storage devices may comprise any one of several media typesincluding, for example, magnetic, optical or semiconductor storagemedia. Such storage devices may also comprise any type of long term,short term, volatile or non-volatile memory devices. However, these aremerely examples of a storage medium, and claimed subject matter is notlimited in these respects. The term “storage medium” does not apply tovacuum.

Unless specifically stated otherwise, as apparent from the followingdiscussion, it is appreciated that throughout this specificationdiscussions utilizing terms such as “processing,” “computing,”“calculating,” “selecting,” “forming,” “enabling,” “inhibiting,”“locating,” “terminating,” “identifying,” “initiating,” “detecting,”“obtaining,” “hosting,” “maintaining,” “representing,” “estimating,”“receiving,” “transmitting,” “determining” and/or the like refer to theactions and/or processes that may be performed by a computing platform,such as a computer or a similar electronic computing device, thatmanipulates and/or transforms data represented as physical electronicand/or magnetic quantities and/or other physical quantities within thecomputing platform's processors, memories, registers, and/or otherinformation storage, transmission, reception and/or display devices.Such actions and/or processes may be executed by a computing platformunder the control of machine-readable instructions stored in a storagemedium, for example. Such machine-readable instructions may comprise,for example, software or firmware stored in a storage medium included aspart of a computing platform (e.g., included as part of a processingcircuit or external to such a processing circuit). Further, unlessspecifically stated otherwise, processes described herein, withreference to flow diagrams or otherwise, may also be executed and/orcontrolled, in whole or in part, by such a computing platform.

Wireless communication techniques described herein may be in connectionwith various wireless communication networks such as a wireless widearea network (WWAN), a wireless local area network (WLAN), a wirelesspersonal area network (WPAN), and so on. The term “network” and “system”may be used interchangeably herein. A WWAN may be a Code DivisionMultiple Access (CDMA) network, a Time Division Multiple Access (TDMA)network, a Frequency Division Multiple Access (FDMA) network, anOrthogonal Frequency Division Multiple Access (OFDMA) network, aSingle-Carrier Frequency Division Multiple Access (SC-FDMA) network, andso on. A CDMA network may implement one or more radio accesstechnologies (RATs) such as cdma2000 or Wideband-CDMA (W-CDMA), to namejust a few radio technologies. Here, cdma2000 may include technologiesimplemented according to IS-95, IS-2000, and IS-856 standards. A TDMAnetwork may implement Global System for Mobile Communications (GSM),Digital Advanced Mobile Phone System (D-AMPS), or some other RAT. GSMand W-CDMA are described in documents from a consortium named “3rdGeneration Partnership Project” (3GPP). Cdma2000 is described indocuments from a consortium named “3rd Generation Partnership Project 2”(3GPP2). 3GPP and 3GPP2 documents are publicly available. A WLAN maycomprise an IEEE 802.11x network, and a WPAN may comprise a Bluetoothnetwork, an IEEE 802.15x, for example. Wireless communicationimplementations described herein may also be used in connection with anycombination of WWAN, WLAN and/or WPAN.

A device and/or system may estimate a device's location based, at leastin part, on signals received from satellites. In particular, such adevice and/or system may obtain “pseudorange” measurements comprisingapproximations of distances between associated satellites and anavigation satellite receiver. In a particular example, such apseudorange may be determined at a receiver that is capable ofprocessing signals from one or more satellites as part of a SatellitePositioning System (SPS). Such an SPS may comprise, for example, aGlobal Positioning System (GPS), Galileo, Glonass, to name a few, or anySPS developed in the future. To determine its position, a satellitenavigation receiver may obtain pseudorange measurements to three or moresatellites as well as their positions at time of transmitting. Knowingthe satellite's orbital parameters, these positions can be calculatedfor any point in time. A pseudorange measurement may then be determinedbased, at least in part, on the time a signal travels from a satelliteto the receiver, multiplied by the speed of light. While techniquesdescribed herein may be provided as implementations of locationdetermination in a GPS and/or Galileo types of SPS as specificillustrations, it should be understood that these techniques may alsoapply to other types of SPS, and that claimed subject matter is notlimited in this respect.

Techniques described herein may be used with any one of several SPS,including the aforementioned SPS, for example. Furthermore, suchtechniques may be used with positioning determination systems thatutilize pseudolites or a combination of satellites and pseudolites.Pseudolites may comprise ground-based transmitters that broadcast aPseudo Random Noise (PRN) code or other ranging code (e.g., similar to aGPS or CDMA cellular signal) modulated on an L-band (or other frequency)carrier signal, which may be synchronized with GPS time. Such atransmitter may be assigned a unique PRN code so as to permitidentification by a remote receiver. Pseudolites may be useful insituations where SPS signals from an orbiting satellite might beunavailable, such as in tunnels, mines, buildings, urban canyons orother enclosed areas. Another implementation of pseudolites is known asradio-beacons. The term “satellite”, as used herein, is intended toinclude pseudolites, equivalents of pseudolites, and possibly others.The term “SPS signals”, as used herein, is intended to include SPS-likesignals from pseudolites or equivalents of pseudolites.

As used herein, a handheld mobile device or a mobile station (MS) refersto a device that may from time to time have a position or location thatchanges. The changes in position and/or location may comprise changes todirection, distance, orientation, etc., as a few examples. In particularexamples, a mobile station may comprise a cellular telephone, wirelesscommunication device, user equipment, laptop computer, other personalcommunication system (PCS) device, and/or other portable communicationdevice. A mobile station may also comprise a processor and/or computingplatform adapted to perform functions controlled by machine-readableinstructions.

This application is related to the following applications, each filedconcurrently with this application and each included in their entiretyherein: U.S. patent application Ser. No. 12/208,249, entitled “OptimizedOrdering of Assistance Data in a Mobile Radio Network” by Kirk AllanBurroughs; U.S. patent application Ser. No. 12/208,270, entitled“Improve GPS Yield For Emergency Calls in a Mobile Radio Network” byThomas Rowland; and U.S. patent application Ser. No. 12,208,297,entitled “Dynamic Measure Position Request Processing in a Mobile RadioNetwork” by Thomas Rowland.

FIGS. 1A, 1B and 1C show various components and interfaces in a wirelessnetwork. For simplicity, the description below uses general terminologyused in wireless networks or specific terminology used with reference toa specific standard though the techniques described herein may beapplicable to several different wireless network standards. For example,such a wireless network includes Code Division Multiple Access (CDMA)system, which is a high-capacity digital wireless technology that waspioneered and commercially developed by QUALCOMM Incorporated. Anotherwireless network includes Global System for Mobile Communications (GSM),which used an alternative digital wireless technology. Yet anotherwireless network includes Universal Mobile Telephone Service (UMTS),which is a next generation high capacity digital wireless technology.

FIG. 1A includes a mobile station (MS 10), a base station subsystem (BSS20) including a base transceiver station (BTS 22) and a base stationcontroller (BSC 24), a mobile switching center (MSC 30), a publicswitched telephone network (PSTN) and a serving mobile location center(SMLC). The MS 10 is any mobile wireless communication device, such as acell phone that has a baseband modem for communicating with one or morebase stations. MSs referenced in this disclosure include a GPS receiveror equivalent receiver to provide position determination capabilities.The term GPS used below is used in the generic sense to mean a satelliteor pseudosatellite system. The MS 10 and the BTS 22 communicatewirelessly over an RF air interface referred to as the U_(m) interface.One or more MSs 10 may communicate with the BTS 22 or BSS 20 at onetime. Internally to the BSS 20, the BTS 22 may communicate to the BSC 24over an Abis interface. One BSC 24 may support several BTSs 22 in adeployed network. Herein, when referring to U_(m) air interface messagesfrom the network (downlink) and from the MS 10 (uplink), these messagesmay be referred to as being communicated using a BTS 22 or equivalentlyusing a BSS 20. An L_(b) interface couples a BSC 24 with an SMLC 50.When referring to L_(b) interface downlink and uplink messages, thesemessages may be referred to as being communicated using a BSC 24 orequivalently using a BSS 20. One or more BSCs 24 and/or BSSs 20 may becoupled to the MSC 30 using an A interface. The MSC 30 connects aswitched circuit from a PSTN 40 to the MS 10 to provide a voice call tothe public network. Other network elements or network components may beconnected to the BSS 20, MSC 30 and PSTN 40 to provide other services.

For example, the SMLC 50 may be coupled to the network to providelocation services, and is shown connected to the BSC 24 over an L_(b)interface. The SMLC 50 may also be connected to the wireless network viathe MSC 30 and an L_(s) interface. The SMLC 50 provides overallco-ordination for locating mobile stations and may also calculate thefinal estimated location and estimated accuracy achieved. The SMLC 50 isused generically herein to mean a positioning server, which are alsoreferred to as a Position Determination Entity (PDE) within CDMAnetworks, Serving Mobile Location Center (SMLC) within GSM networks, andStand-Alone (A-GPS) SMLC (SAS) within WCDMA cellular networks.

A positioning server is a system resource (e.g. a server) typicallywithin the wireless network, working in conjunction with one or more GPSreference receivers, which is capable of exchanging GPS relatedinformation with an MS. In an MS-Assisted A-GPS session, the positioningserver sends GPS Assistance Data to the MS to enhance the signalacquisition process. The MS may return pseudo-range measurements back tothe positioning server, which is then capable of computing the positionof the MS. Alternatively, in an MS-Based A-GPS session, the MS sendsback computed position results to the positioning server.

FIG. 1B shows a layered model of the U_(m) and L_(b) interfaces. Layersin the MS 10 (target MS) include a first layer referred to as thephysical layer, layer one or L1, a second layer referred to as L2(LAPDm), a third layer referred to as a radio resource (RR) layermodeled after the GSM 04.08 specification, and finally an applicationlayer. In this case, the application layer is a Radio Resource LocationProtocol (RRLP) defined in the GSM 04.31 and GSM 04.35 recommendations.The BSS 20 (shown as BSC 24) has a corresponding layered model includingL1, L2 (LAPD) and RR layers, with the RRLP messages passing through theBSS 20. The BSS 20 relays the lower layers as required to the SMLC 50over the L_(b) interface. The layers include MTP, SCCP BSSLAP-LE andBSSLAP layers, which correspond to MTP, SCCP BSSLAP-LE and BSSLAP layerswithin the SMLC 50. For additional information on the BSSAP-LE andBSSLAP interfaces, see GSM 09.21 and GSM 08.71 recommendations.

Messages passing from network element to network element may passthrough multiple different interfaces and corresponding protocols. Forexample, a message passing from the positioning server SMLC 50 to theBSS 20 to the MS 10 will be communicated as a first message across theL_(b) interface, possibly another message across the Abis interface anda final message across the U_(m) interface. Generally, in the presentdisclosure, a message will be referred to by its application layer andair interface name for simplicity. For example, a request from thepositioning server SMLC 50 destined to the MS 10 may be referred to bythe air interface U_(m) application layer name of RRLP Measure PositionRequest. Additionally, for clarity sake, the BSS 20 and the SMLC 50 maybe referred to collectively as the network 70, which may include a BTS22, a BSC 24 and an SMLC 50 or may include a BSS 20 and an SMLC 50.

FIG. 1C shows a message flow diagram of a normal RRLP session. At timea, the SMLC 50 sends a Request message 80 to the BSS 20 across the L_(b)interface. The BSS 20 re-packages and forwards this request as an RRLPRequest 85 transmitted across the downlink U_(m) air interface to the MS10. Internally, the MS 10 begins an RRLP session and eventually repliesacross the uplink U_(m) air interface with an RRLP Response message 90.The BSS 20 again re-packages and forwards this reply to the SMLC 50 in aResponse message 95 across the L_(b) interface, which the SMLC 50receives as time b. Hereinafter, such request and responses from and tothe SMLC 50 will be referred to as RRLP requests and RRLP responses.

The 3GPP RRLP application layer currently supports five messages. Thefirst message is an RRLP Measure Position Request message used on thedownlink. The network 70 uses this message to request locationmeasurements or a location estimate from the MS 10. The message includesinstructions for the MS 10 and may also include Assistance Data for theMS 10. Assistance Data is described in additional detail below. Thesecond message is an RRLP Measure Position Response message used on theuplink and complements the RRLP Measure Position Request message. The MS10 uses this message to respond to the network 70 with position estimateinformation and other position related information. The RRLP MeasurePosition Request message and the RRLP Measure Position Response messageoperate together to begin and terminate an RRLP session.

The third and fourth messages also operate together to begin andterminate an RRLP session. The third message is another downlink messagereferred to an RRLP Assistance Data message, which the network 70 usesto send Assistance Data to the MS 10. Assistance Data optionallyincludes Enhanced Observed Time Difference (E-OTD) reference BTSinformation (e.g., BTS signaling and position information) and E-OTDmeasurement information for up to eight additional BTSs. The fourthmessage is an RRLP Assistance Data Acknowledgment (Ack) message used onthe uplink. The RRLP Assistance Data Ack message is simply used by theMS 10 to acknowledge, to the network 70, receipt of the RRLP AssistanceData message. The fifth message is an atypical message called an RRLPProtocol Error, which may be used either on the downlink or the uplinkto report an error in the protocol.

FIG. 2 shows a message flow diagram of a typical position locationprocess using RRLP sessions. The MS 10 and the network 70 may be viewedas a client-server model with the MS 10 acting as the client and thenetwork 70 acting as the server. An RRLP session begins with a requestfrom the network 70 and typically ends with a response from the MS 10.At time a, a position location process begins with the network 70 and MS10 communicating an RRLP Assistance Data message 110. That is, thenetwork 70 sends the an RRLP Assistance Data message 110 to the MS 10and the MS 10 begins a new RRLP session on receipt of the RRLPAssistance Data message 110. Normally, shown at time b, the MS 10completes the RRLP session with an acknowledgement response referred toas an RRLP Assistance Data Ack message 112.

At time c, the network 70 sends an RRLP Measure Position Request message120, which includes a position instruction and optionally AssistanceData. The position instruction from the network 70 includes a maximumresponse time (NW Response) set by the network (NW) and minimum accuracy(NW Accuracy), also set by the network (NW). In response to receivingthe RRLP Measure Position Request message 120, a known mobile stationstarts its GPS engine. GPS is used generically to refer to a positioningsystem using satellite vehicles (SVs) and/or pseudo-satellites. Engineis also used generically as hardware and/or firmware and/or softwarethat operates to process data. The MS 10 then determines one or moreposition fixes with each having an estimated uncertainty.

Once the estimated uncertainty is less than or equal to the minimumnetwork accuracy (NW Accuracy) signaled by the network 70, or once theMS 10 has been computing a fix for as long as allowed by the networkresponse time (NW Response) parameter, location processing stops. Asshown at time d, the MS 10 reports the computed fix in an RRLP MeasurePosition Response message 122 and also shuts down the GPS engine. Thedifference in time between time references c and d may be substantial(e.g., 45 seconds to several minutes). One goal in positiondetermination is to minimize this acquisition time. Another goal is toreduce the uncertainty of a provided fix.

FIG. 3 shows pseudo segmentation of Assistance Data. Assistance Data mayinclude position data on one or more satellite vehicles (SVs). Becausethe Assistance Data typically contains information on 8 to 12 or moresatellites, the Assistance Data is separated into multiple blocks ofpseudo segmented Assistance Data messages, with each block containinginformation on one, two, three or four satellites. In the example shown,the Assistance Data is segmented into three pseudo segments. The firsttwo blocks may contain information on three or four satellites and thefinal block may contain information on one, two or three satellites fora total of seven to eleven satellites for the example shown.

The first block of the Assistance Data is communicated from the network70 to the MS 10 at time a in a first RRLP Assistance Data message 140.Once received, a first RRPL session begins but quickly terminates whenthe MS 10 sends an RRLP Assistance Data Ack message 142 to the network70 at time b.

The second block of the Assistance Data is communicated from the network70 to the MS 10 at time c in a second RRLP Assistance Data message 144.Once received, a second RRPL session begins. In this example at time d,the MS 10 does not have time to transmit an acknowledgement messagebefore it receives a second RR message (referred here as an extra RRmessage 130), which terminates the RRLP session created by message 144.The extra RR message may be any of several different RR messages. Forexample, a higher priority RR message such as a handover message mayhave been transmitted to the MS 10.

A session is termed preempted if either the MS 10 receives a part of thedownlink RRLP message or none of the downlink RRLP message. Preemptionoccurs when a message is placed in an outgoing queue of the network fortransmission. In some cases, before the downlink RRLP message may becomplete transmitted, the remainder of the message not yet transmittedis purged from the queue for the higher priority message. In thesecases, the MS 10 may have received some but not the entire downlink RRLPmessage. In other cases, the downlink RRLP message is purged before thefirst bit of the message is even transmitted over the air interface. Inthese cases, the session is also considered preempted, however, the MS10 has no knowledge of the session's existence. Often a preemptionoccurs when a downlink RRLP message is long, or when longer messages areahead of it (i.e., other messages scheduled for an earlier transmissiontime) in the same downlink queue.

On the other hand, a session is referred to as aborted if the MS 10receives the entire downlink RRLP message but has not yet completelysent a response, such as an RRLP Assistance Data Ack message. Anabortion usually occurs when the MS 10 takes a relatively long period oftime to respond to a downlink RRLP message.

In both the preemption and abortion cases, the existing session in theMS 10 and/or network 70 is terminated. One goal is for the MS 10 toquickly respond to the downlink RRLP messages, thereby minimizingaborted sessions. Another goal is for the network to send shorterdownlink RRLP messages thereby keeping the queue less full andminimizing preempted sessions. Pseudo segmentation targets the secondgoal of having shorter downlink RRLP messages thus reducing the chanceof a preempted session but does not address the first goal of quicklyresponding to downlink messages as described further below withprocessing associated with RRLP Measure Position Request messages.

Hereinafter, the terms abortion, abort or aborted will be used inreference to terminating a session caused by either an abortion sessiondue to a receipt of an extra RR message or a preemption in the downlinkqueue by a higher priority downlink message.

To recover from an aborted session, the network 70 transmits a rebidmessage. A rebid message is a subsequent transmission of a messagepreviously placed in a downlink queue. In the example shown at time e,the second block of Assistance Data is included in a rebid RRLPAssistance Data message 148, which begins a third RRLP session at the MS10. The MS 10 acknowledges receipt with another RRLP Assistance Data Ackmessage 150 to the network 70 at time f.

The final block of Assistance Data is transmitted from the network 70 tothe MS 10 at time g in an RRLP Measure Position Request message 120,which is received by the MS 10 and begins a forth session in thisexample. The MS 10 is now instructed to begin location determination,which may take 10s of seconds to several minutes. During the period fromreceiving the instruction to transmitting a response, the session isvulnerable to session abortions by an extra RR message. In this example,the final session is not aborted but rather the MS 10 responds with anRRLP Measure Position Response messages 122 at time h.

FIGS. 4 and 5 illustrate halting position determination based on a MS 10receiving an extra RR message. In FIG. 4 at time a, the network 70 sendsthe MS 10 an RRLP Assistance Data message 110, then at time b, the MS 10replies with an RRLP Assistance Data Ack message 112. The network 70 andthe MS 10 may repeat this exchange of messages several times to providenext to all of the Assistance Data to the MS 10 prior to starting theGPS engine. At time c, the network 70 sends the MS 10 an RRLP MeasurePosition Request message 120 with the final block of Assistance Data. Atthis point, the MS 10 starts its GPS engine and begins positionlocation.

At time d, the network 70 sends the MS 10 an extra RR message 130 (thatis, a message that the MS 10 was not expecting to receive because it isin an ongoing session). This extra RR message 130, which occurred beforethe MS 10 was able to transmit a reply message, causes the MS 10 toabort the current session started by the RRLP Measure Position Requestmessage 120. As part of aborting the session, the MS 10 shuts down theGPS engine, terminates the position location process, responds to theextra RR message 130 and waits for the next request from the network 70.After a short delay of Δt time e (where Δt=e−d), the network 70transmits a rebid of the RRLP Measure Position Request message 120A,which cause the MS 10 to restart its GPS engine and begin positionlocation again. This process of sending rebids of message 120A followedby an interruption by an extra RR message 130 may occur several timesbefore the MS 10 is able to determine its position within the networkresponse time and accuracy parameters provided. At time f, the MS 10reports a determine position to the network 70 in an RRPL MeasurePosition Response message 122.

FIG. 5 shows this message exchange in state diagram form. When the MS 10receives an RRLP Measure Position Request message 120, the MS 10 entersstate 200, which starts the GPS engine and begins positiondetermination. In normal uninterrupted operation, the MS determines aposition 220 and reports the position to the network by entering state230, which sends an RRPL Measure Position Response message 122. When afix cannot be determined within the provided network response time(e.g., when a response time timeout occurs), the MS 10 may exit state200 and enter state 230 where the MS 10 replies with the RRPL MeasurePosition Response message 122 containing a fix with an accuracy worsethan requested by the network.

The state diagram shows other situations that may occur. For example,the MS 10 will exit state 200 and enter state 210 when it receives anextra RR message 130. At state 210, the MS 10 shuts down the GPS engineand halts position determination. The MS 10 exits state 210 and reentersstate 200 when it receives a rebid RRLP Measure Position Request message120A. Eventually, the MS 10 ordinarily either determines a position ortimes out 220 and enters state 230 to respond with the RRPL MeasurePosition Response message 122.

In the position location process described above, an MS 10 waits untilan RRLP Measure Position Request message 120 before starting its GPSengine and shuts down its GPS engine when it receives an extra RRmessage 130, thereby minimizing the duration of time that the GPS engineis running. By starting the GPS engine in response to receiving the RRLPMeasure Position Request message 120, the MS 10 knows the network 70needs a position fix. In any other case, no guarantee exists that thenetwork 70 will request a position fix from the MS 10. Therefore by notstarting before this time, the MS 10 saves battery power. The MS 10 alsosaves battery power by shutting down the GPS engine once the RRLPsession is over (e.g., as a result of an abortion or reporting theposition fix).

In accordance with some embodiments of the present invention, advantagesmay be realized by not following this known procedure and insteadstarting the GPS engine in anticipation of receiving an RRLP MeasurePosition Request message 120. Furthermore, advantages may be realized bynot shutting down the GPS engine once the RRLP session is over. At thecost of battery power, the GPS engine may be started early (i.e., beforean RRLP Measure Position Request message 120 is received) and maycontinue the position determination process even if the RRLP session isterminated.

FIGS. 6 and 7 show events that start and shutdown a GPS engine, inaccordance with embodiments of the present invention. The state diagramof FIG. 6 shows two states: state 800 where the GPS engine is notrunning and state 810 where the GPS engine has started and the positiondetermination process has begun. Several user-side and network-sidetriggering events may occur that initiate an early starting of the GPSengine in anticipation of a future receipt of an RRLP Measure PositionRequest message 120. A triggering event occurs after beginning a runtimeoperation. That is, a triggering event is not simply turning on themobile station, which puts the mobile station into runtime operation.Some devices always run a GPS engine thus no triggering event exists tostart a GPS engine. A triggering event is not a user operation tospecifically turn on a GPS location function of the mobile station. Atriggering event is an event that typically does not turn on a GPSengine. Also, triggering event occurs prior to receiving an RRLP MeasurePosition Request message, which is a message that typically turns on aGPS engine.

First at 820, if the MS 10 detects the triggering event that anEmergency Services (ES) call has been initiated, the MS 10 maytransition from state 800 to state 810. Another user-side initiatedtransition may occur if the MS 10 received a message from a mobilestation application (MS App) indicating a position fix is needed. Thenetwork-side events may also initiate transition from state 800 to state810. For example at 840, if the MS 10 receives the triggering event of anew RRLP Assistance Data message, the MS 10 may transition from state800 to state 810. At 850, if the MS 10 receives the triggering event ofa value added services (VAS) message, the MS 10 may transition fromstate 800 to state 810. For completeness, at 860, the known process oftransitioning states is shown by receipt of an RRLP Measure PositionRequest message 120.

Besides starting early as described with reference to FIG. 6, shuttingdown of the GPS engine may be advantageously postponed as shown in FIG.7, which also includes two states. In state 900, the GPS engine isrunning (e.g., due to one of the events described above). In state 910,the GPS engine is shut down. Several events may trigger transitioningfrom state 900 to state 910 to shut down the GPS engine. For example, aposition may be derived or a time out may occur. At 920, the transitionoccurs as a result of recently sending an RRPL Measure Position Responsemessage 122 when there is no other significant need for the engine tocontinue running such as an MS APP waiting for a better position fix.The transition may also occur when a position fix has just been reportedto an MS APP and the MS 10 is not anticipating an RRLP Measure PositionRequest message 120 and not expecting to send an RRPL Measure PositionResponse message 122.

Abnormal cases may also cause the transition. For example at 940, if theMS 10 has been anticipating an RRLP Measure Position Request message 120(e.g., due to events 820 or 840 described above) but has not receivedthe message within a predetermined period of time (e.g., 45, 60 or 90seconds or a value selected from a range of times of 30-60, 30-90,30-120, 30-180, 30-240, 60-90, 60-120, 60-180, 60-240, 90-120, 90-180,90-240, 120-180, 120-240, or the like as would be understood by someoneskilled in the art), the MS 10 may shut down its GPS engine. Similarlyat 940, if the GPS engine has been running too long (e.g., 120 or 180seconds), the MS 10 may time out and shutdown the GPS engine to savebatter power.

FIG. 8 shows a message flow diagram highlighting early locationdetermination, in accordance with embodiments of the present invention.One goal is to start the GPS engine as soon as the MS 10 expects oranticipates a future RRLP Measure Position Request message 120 from anetwork 70. At time a, the MS 10 recognizes dialed digits for anemergency services call (e.g., “911” in the U.S., “112” in Europe or“119” in Japan). Once the call is recognized as an emergency servicescall, the MS 10 may begin position location by starting its GSP enginein expectation of a need for a location fix of the MS 10.

At time b, the network 70 sends an RRLP Assistance Data message 110 tothe MS 10. In response, at time c, the MS 10 replies with an RRLPAssistance Data Ack message 112. This process of sending messages 110and 112 may repeat until the network 70 has transmitted sufficientAssistance Data. Finally, at time d, the network 70 sends an RRLPMeasure Position Request message 120 to the MS 10. The MS 10 continuesdetermining its location. Next at time e, the MS 10 replies to thenetwork 70 with an RRLP Measure Position Response message 122 containingits determined position.

FIGS. 9 and 10 illustrate a method of continuing position determinationafter an extra RR message 130 is received, in accordance withembodiments of the present invention. Another goal is to continueoperating the GPS engine through minor abnormal events. In FIG. 9, anextra RR message 130 aborts a current measurement session but the MS 10continues position location processing and does not interrupt its GPSengine. At time a, the MS 10 receives an RRLP Assistance Data message110 from the network 70. In response at time b, the MS 10 replies withan RRLP Assistance Data Ack message 112. Again, this process of sendingmessages 110 and 112 may repeat until the network 70 has transmittedsufficient Assistance Data.

At time c, the network 70 sends an RRLP Measure Position Request message120 to the MS 10. At this point the GPS engine is already running;either based on the MS 10 recognizing an emergency call or othertriggering event. At time d, before the network 70 receives a reply, thenetwork 70 interrupts the RRLP session begun at time c. Known mobilestations terminate the RRLP session and also shutdown the GPS engine.Here, the MS 10 leaves the GPS engine uninterrupted to allow it tocontinue the position location process.

Finally at time e, the network 70 re-sends an RRLP Measure PositionRequest message 120A to the MS 10 in a rebid process. Again, the MS 10does not restart the GPS engine but rather continues the locationprocess. As stated above, processes of aborting and rebidding mayrepeat. Next, at time f, the MS 10 replies to the network 70 with anRRLP Measure Position Response message 122 containing its determinedposition.

FIG. 10 shows a state diagram. The MS 10 enters state 300 when atriggering event occurs. Triggering events include receiving an RRLPMeasure Position Request message 120, receiving an RRLP Assistance Datamessage 110, recognizing initiation of an emergency services call andthe like. In state 300, the MS 10 continues position determination ifalready running or begins position determination by starting the GPSengine if not already started.

Normally, the MS 10 exits state 300 either when position is determinedor when a time out occurs (shown as transition 310) and enters state320. The time out, for example, may occur when the MS 10 determines thatthe network 70 is expecting a measurement within a small predeterminedamount of time. In some cases, the MS 10 exits state 300 and entersstate 330 when the MS 10 receives an extra RR message 130, which abortsthe current RRLP session before the MS 10 can send its response.

In state 330, the MS 10 aborts the current RRLP session but continuesposition determination. Upon receipt of a rebid RRLP Measure PositionRequest message 120A, the MS 10 enters state 340 but again continues theposition determination process. Once the MS 10 determines the positionor a time out occurs (shown as transition 340), the MS 10 exits state340 and enters state 320. In state 320, the MS 10 sends its RRLP MeasurePosition Response message 320 to the network 70.

FIGS. 11 and 12 illustrate a method of optimally ordering downloadedAssistance Data, in accordance with embodiments of the presentinvention. Assistance Data may be transmitted in one or more (pseudosegmented) RRLP Assistance Data messages 110 and/or in an RRLP MeasurePosition Request message 120. Optimally ordering the communication ofAssistance Data from the network 70 to the MS 10 allows the MS 10 toadvantageously begin the position determination process early andactively use segments of the Assistance Data before instructed to do soby the RRLP Measure Position Request message 120.

FIG. 11 shows an optimal ordering of segmented Assistance Data 400. Thefirst segment includes reference information 410 including a satellitetime and a coarse MS location 420. The first and remaining segmentsinclude satellite vehicle position information (including almanac andephemeris data) 430. The satellite vehicle position information 430 isordered from most optimal 440, to next most optimal 450, and continuesto least optimal 460. Not all satellites available need be placed inthis optimally ordered Assistance Data list.

Optimal ordering of the satellites may take into account one or morefactors to provide the MS 10 with a set of satellite most likely to beviewable and helpful to the MS 10 in quickly determine its location. Forexample, knowledge of coarse MS location may be used to lookup satellitepositions shown empirically to be visible to mobile stations withsimilar coarse MS locations. The network 70 may look for satellites tobe in a region of space shown by observation or experimentation to beavailable to a mobile station having a similar or the same coarse MSlocation.

Furthermore, knowledge of the coarse MS location may be used todetermine a general characteristic of the environment. Thisenvironmental characteristic may used to identify the best satellites toallow the MS 10 to determine its location. The coarse MS location mayidentify the MS 10 as being situated, for example, in a rural landscape(e.g., in a flat rural environment), in a mountainous landscape (e.g.,in a north-south oriented valley or along the west face of a mountain),or in an urban landscape (e.g., in a dense downtown with high-risebuildings). If the coarse MS location indicates the MS 10 most likelyhas an unobstructed view of the sky, a network 70 may first providesatellite position information for an orthonormal or pseudo-orthonormalset of satellites, for example, three satellites closest to 45 degreesfrom the horizon separated by 120 degrees from one another. Any two ofthese three satellites would be approximately orthogonally oriented withrespect to the mobile station. That is, a first line between the firstsatellite to the mobile station and a second line between the secondsatellite to the mobile station form a right angle (orthonormal) or anangle between 60 and 120 degrees (approximately orthogonally oriented).If the coarse MS location suggests that the MS 10 would not be able tosee satellites located in a particular region of space (e.g., if amountain blocks the eastern sky), then position information for thosesatellites may be lower in the optimal list of satellites (or evenremoved from the list entirely).

In addition to the reference information 410, the first segment ofAssistance Data may also include information on one or two satellites,as provided by the allowable message length. The first segment includessatellite position information that is the most optimal 440 to the MS10. The second segment of Assistance Data includes satellite positioninformation for the next two, three or four most optimal satellites 450.Each subsequent segment of Assistance Data includes satellite positioninformation for equal or less and less optimal satellites until the setof least optimal 460 satellites is reached.

FIG. 12 shows a flow chart for ordering and sending segments ofAssistance Data. At step 500, the network 70 orders a list of satellitesfrom most to least optimal to the MS 10 to produce an ordered list, bothlists which may also be stored in memory within the network 70. Theorder may be specific for each MS 10. For example, the order may dependon the coarse MS location. At step 510, the network 70 sends the firstsegmented RRLP Assistance Data message 110 including the referenceinformation (i.e., reference time & coarse MS location) and satelliteposition information for most optimal satellites.

At step 520, the network 70, for example using a controller orcontroller logic within the network 70, determines if it is time to sendan RRLP Measure Position Request message 120. The network 70 maydetermine that it is time to send an RRLP Measure Position Requestmessage 120 if sufficient Assistance Data has already been sent to theMS 10. If the MS 10 has satellite position information for at least apredetermined number of satellites (e.g., 4-14 satellites), then thenetwork 70 may determine that the MS 10 has a sufficient amount ofAssistance Data. Alternatively, if the predetermined number ofsatellites is not reached but no more satellite information is availableto send in an Assistance Data message, the network may either transmitthe RRLP Measure Position Request message (with or without a final pieceof Assistance Data) or may set a timer such that the RRLP MeasurePosition Request message is sent to receive an RRLP Measure PositionResponse message just in time. Alternatively, the network 70 maydetermine that the MS 10 has a sufficient amount of Assistance Data ifthe time remaining before the position fix is needed by the network 70is less than a predetermine amount of time. In this case, the network 70will determine that it is time to send the RRLP Measure Position Requestmessage 120 if a time out has occurred. Alternatively, the network 70may determine that it is time to send the RRLP Measure Position Requestmessage 120 if all Assistance Data have previously been sent.

If it is not time to send the RRLP Measure Position Request message 120,the network 70 may proceed to step 530. If it is time to send the RRLPMeasure Position Request message 120, the network 70 may proceed to step540. At step 530, the network 70 send the next segmented RRLP AssistanceData message 110 including position information for the group of nextmost optimal satellites then returns to step 520. This loop betweensteps 520 and 530 may continue multiple times. At step 540, the network70 sends an RRLP Measure Position Request message 120. The RRLP MeasurePosition Request message 120 may contain a final segment of AssistanceData. Alternatively, the RRLP Measure Position Request message 120 maybe void of any Assistance Data as described in detail below.

FIGS. 13 and 14 show a method of sending just-in-time position requests,in accordance with embodiments of the present invention.

In FIG. 13, at time a, the network 70 begins an RRLP session by sendingan RRLP message such as an RRLP Measure Position Request message 120.This scenario assumes the network 70 successfully sent one or more anRRLP Assistance Data messages 110 to the MS 10 or that the MS 10 alreadyhas Assistance Data in its memory. In the example shown, the network 70requires a position fix from the MS 10 in approximately 35 seconds. Attime b, the RRLP session is aborted due to some other RR message 131.

In some cases, the RRLP message 120 shown at time a may still be in anoutgoing queue of the network 70, thus the MS 10 has not received anRRLP message and has not started an RRLP session. In this case, theother RR message 131 preempts the RRLP message 120 by removing it fromthe queue before it can successfully and completely be transmitted outof the queue. Due to the MS 10 previously receiving a triggering event,such as a first RRLP Assistance Data message (not shown), the GPS engineis already running. During each subsequent message, the GPS enginecontinues to the position determination process uninterrupted.

The network 70 at time c determines that only a minimum about of timeremains until a position fix is needed (e.g., approximately 4 secondsremain). The network 70 sends an RRLP Measure Position Request message120B to the MS 10. This message 120B is sent at a time (time c) suchthat a response will be received just in time (at time d). In someembodiments, the RRLP Measure Position Request message 120B is sent withNW Response Time and NW Accuracy parameters but without Assistance Data.The RRLP Measure Position Request message 120 may include a shorttimeout (e.g., NW Response Time represents 2 or 4 seconds) for which theMS 10 must return a position fix and may contain a low value foruncertainty (NW Accuracy indicates a high accuracy, for example,approximately 10 meters). Alternatively, the RRLP Measure PositionRequest message 120 may include a position accuracy parameter set toallow a large position uncertainty (NW Accuracy indicates a lowaccuracy, for example, approximately 250 meters). At time d, the network70 receives an RRLP Measure Position Response message 122 from the MS 10just in time when approximately 0 seconds or close to 0 seconds remain.

This just-in-time procedure may be invoked because a rebid was necessarydue to an earlier interrupted RRLP session. In some cases theinterrupted RRLP session must be a session started by an earlier RRLPMeasure Position Request message 120 (as shown). In some cases theinterrupted RRLP session must be a session started by an RRLP AssistanceData message 110. In some cases the interrupted RRLP session may be asession started by either an earlier RRLP Measure Position Requestmessage 120 or an RRLP Assistance Data message 110.

FIG. 14 shows a process in a network 70 for just-in-time positionrequests and responses. At step 600, the network 70 determines a futuretime that an RRLP Measure Position Response message 122 is needed. Atstep 610, the network 70 sets a timer, a schedule or the like and waitsuntil just before location data is needed (e.g., 4 seconds before).During this waiting time after the last RRLP message and before thejust-in-time RRLP Measure Position Request message 120, the network maysend other RR messages and not interrupt the mobile station's positiondetermination process.

At step 620, the network 70 sends an RRLP Measure Position Requestmessage 120. This message 120 is sent without Assistance Data at a timegiving the MS 10 sufficient time to respond. At step 630, the network 70receives an RRLP Measure Position Response message 122 just before theposition is needed. As mentioned above, this just-in-time process may beimplemented for all RRLP Measure Position Request messages 120 beingtransmitted by the Network 70. Waiting to send an RRLP Measure PositionRequest message 120 until just before a position fix is needed (e.g., ifexperiencing rebids) helps to reduce occurrences of aborted sessions andspares channel bandwidth. Alternatively, this process may be implementedif one or more abortions and/or preemptions have occurred within thepresent communication with this MS 10. Alternatively, this process maybe implemented if one or more abortions or preemptions have occurred incommunications with other mobile stations in this cell, for example, formobile stations having similar coarse MS locations.

FIGS. 15 and 16 show a method of delaying (or dropping) new RR messagesto avoid aborted sessions, in accordance with embodiments of the presentinvention.

FIG. 15 shows a method of minimizing rebids between a network 70 and aMS 10 in a wireless network. At time a, the network 10 sends an RRLPRequest message 100 thereby opening a session. The RRLP Request message100 may be either an RRLP Assistance Data message 110 or an RRLP MeasurePosition Request message 120. At time b, before the network 10 hasreceived a response from the MS 10, the network 70 determines, while theRRLP session is still open, a new RR message is ready to be sent fromthe network 70 to the MS 10. In known systems, the network 70immediately sends this new RR message thereby aborting the current RRLPsession. According to embodiments of the present invention, the network70 waits, if allowable, to send new RR messages to avoid a current RRLPsession from being aborted. That is, to avoid aborting the RRLP session,the network 70 holds the new RR message until after an RRLPResponse/Acknowledgement message 102 is received thereby causing theRRLP session to close normally. Based on the particular new RR message,the network 70 may either wait to send the new RR message or drop thenew RR message entirely. At time c, the network 70 receives andrecognizes the RRLP Response/Acknowledgement message 102. Shortly after,at time d, if the new RR message was not dropped, the network 70 sendsthe new RR message after the RRLP session is closed, thus avoidingaborting the RRLP session.

In FIG. 16 at step 650, the network 70 sends an RRLP request message. Atstep 660, before the RRLP session is closed, the network 70 determinesit has a new RR message ready to be sent to the MS 10. At step 670, thenetwork 70 determines whether it is allowable to delay (or drop) thesending of the new RR message. If it is not allowable, the network 70sends the new RR message at step 690, thus unavoidably aborting thecurrent RRLP session. At step 680, the network 70 waits for and thenreceives the RRLP Response/Acknowledgement message 102. If the new RRmessage was delayed, processing continues to step 690 before completingprocessing. If the new RR message was dropped, there is no new RRmessage remaining to be sent and processing is complete.

FIGS. 17, 18, 19, 20 and 21 illustrate a method of varying an accuracyparameter to balance response time and accuracy in an emergency services(ES) call, in accordance with embodiments of the present invention.

FIG. 17 shows an example of call flow processing for an emergencyservices (ES) call to use enhanced accuracy when time is available. Attime a (t=0), the MS 10 identifies an ES call. In response toidentifying the ES call, the MS 10 starts the GPS engine. The MS 10 mayset an activity timer to a large value (e.g., Act_timer=40 seconds). Onepurpose for an activity time is to monitor the activity (or inactivity)of messages between the network 70 and the MS 10. If there is noactivity for the duration of time, the activity timer will timeout andthe GPS engine will be shutdown.

At time b, the network 70 sends a first RRLP Assistance Data message140. This first message 140 contains the reference information 410(satellite time and coarse MS location 420 from FIG. 11). It alsocontains satellite position information for the satellites most optimalto the MS 10. At time c, the MS 10 replies with an RRLP Assistance DataAck message 142. At time d and time e, the process of communicatingAssistance Data messages 144 and acknowledgement messages 146 may repeatone or more times to send additional Assistance Data (satellite positioninformation) for the satellites next most optimal to the MS 10.

Next the network 70 prepares an RRLP Measure Position Request message120. The RRLP Measure Position Request message 120 may contain a valuefor a network response time (NW Response Time) parameter. This NWResponse Time parameter may be set to indicate an intermediate responsetime (e.g., a value of 4 corresponds to 16 seconds). The message 120 mayalso contain a network accuracy (NW Accuracy) parameter. This NWAccuracy parameter may be set to indicate an intermediate accuracy oruncertainty (e.g., a value of 19 corresponds to 51.2 meters). Thisparameter and other distance or uncertainty parameters or rangesdescribed herein with specific values are provided as examples only.Other values may be used. A value of 51.2 meters or 245.5 meters, forexample, may be values ranging from 40 to 60 meters, 30 to 70 meters, 40to 100 meters, 40 to 400 meters, 100 to 150 meters, 100 to 250 meters,100 to 300 meters, 100 to 400 meters and the like as a person skilled inthe art understands.

At time f, the network 70 sends the RRLP Measure Position Requestmessage 120. In some cases, a last set of Assistance Data is included inthis message 120. In other cases, the last set of Assistance Data isincluded in the previous message, which was the RRLP Assistance Datamessage 144.

To enhance the accuracy, the MS 10 may use an accuracy value thatrepresents no or little uncertainty. For example, an Act_Accuracyparameter may be set to a value of 0, which represents 0 meters ofuncertainty (the highest value of accuracy). Alternatively, theAct_Accuracy parameter may be set to a value of 1, 2, 3 or 4 torepresent an uncertainty of 1.0, 2.1, 3.3 or 4.6 meters, respectively.Other values representing no or little uncertainty may also be used.

In some cases, where the MS 10 drives this enhanced accuracy process,the MS 10 advantageously sets the Act_Accuracy parameter independentlyfrom the NW Accuracy parameter sent by the network 70. In other cases,where the network 70 drives the enhanced accuracy process, the network70 advantageously and temporarily overrides its standard networkaccuracy (e.g., 51.2 m) and sets the parameter it will later send in anRRLP Measure Position Request message 120 to the accuracy value thatrepresents no or little uncertainty.

Also shown, after time f, the MS 10 resets it activity timer from thecurrent countdown time (e.g., 20 seconds) to a value that matches thenetwork response time (Act_timer=NW Response Time), for example, if theremaining time on the current activity timer is less than the networkprovided response time. In this way, the MS 10 will not prematurelyshutdown the GPS engine before a position measurement fix is determinedand communicated to the network 70. The MS 10 may similarly set a secondcountdown timer to the response time (Act_timer=NW Response Time). Thistimer may be used by the MS 10 to set when the MS 10 sends a determinedposition.

At time g, the elapse time in the example is 36 seconds. The MS 10 hasused the entire allocated network response time in determining aposition fix. Thus, even though the position accuracy has not beenachieved, an enhanced accuracy position has been found potentiallyhaving greater accuracy (or similarly, less uncertainty) than requestedby the standard network accuracy (e.g., 51.2 m).

By lowering this uncertainty parameter to 0, the MS 10 will use theentire allowable network response time in computing a position fix. Bylowering the uncertainty parameter to a low value (e.g., 1, 2, 3, or 4),the MS 10 will most likely use the entire allowable network responsetime unless a position fix may be determined with a low estimateduncertainty. The additional time used by the GPS engine in trying toobtain a position fix with the lowered requisite uncertainty allows theMS 10 an opportunity to produce an enhanced accuracy position fix.

At time g, the MS 10 sends an RRLP Measure Position Response message 122with one of the following components: LocationInfo; GSP-MeasureInfo; orLoctionError. Typically, the MS 10 will respond with the LocationInfocomponent when the MS 10 determines an acceptable position fix or timesout. Alternatively, the MS 10 will respond with the GSP-MeasureInfocomponent when the MS 10 is instructed to provide measurements to thenetwork 70, which allows the network 70 to determine a position based onthis raw data.

FIG. 18 shows another embodiment of call flow processing for anemergency services (ES) call. In this scenario, a position requestmessages is communicated just in time for the MS 10 to reply with anon-time position response. The flow begins as described above withreference to FIG. 17. At time a (t=0), the MS 10 identifies the ES callthen in response, starts the GPS engine. Again, an activity countdowntimer is set (Act_timer=40 seconds). At time b, the network 70 sends afirst RRLP Assistance Data message 140. At time c, the MS 10 replieswith an RRLP Assistance Data message 142. The process may continue tocommunication multiple sets of 140/142 messages.

At time d, this scenario departs from the previously described scenario.At time d, the network 70 has the information it needs to send aposition request message (an RRLP Measure Position Request message 120),however, the network 70 waits to send the message until a predeterminedtime before the network 70 needs a position fix. A standard networkaccuracy may be set to provide sufficient accuracy (NW Accuracy=19,representing 51.2 meters), however, the network set response time isdrastically shortened. For example, the NW Response Time may be set to 2(representing 4 seconds) or to 1 (representing 2 seconds) rather thangiving the MS 10 10s of seconds. This drastically shortened timenormally does not allow a mobile station to determine a position fix.Ordinarily, a mobile station requires tens of seconds to a few minutes.Here, because the MS 10 began its position determination process early(e.g., at time a), it has already been working on it position for tensof seconds.

Again the network 70 prepares an RRLP Measure Position Request message120. The message 120 contains the drastically shortened network responsetime (e.g., NW Response Time=4 seconds) and the network accuracy (e.g.,NW Accuracy=51.2 meters). At time e, the elapse time in the example is32 seconds and the network 70 sends the RRLP Measure Position Requestmessage 120. In this case, the last set of Assistance Data is includedin the previous message (i.e., the last RRLP Assistance Data message140), therefore, this messages 120 is sent without Assistance Data.

In some cases, the accuracy used by the MS 10 is set to a valuerepresenting low accuracy or equivalently a high uncertainty (e.g., avalue of 34 represents 245.5 meters), which may be a predetermined valueor a predetermined configurable value. This accuracy value representinglow accuracy may be set in one of two ways: by the network 70; or by theMS 10.

If the accuracy value is set by the network 70, the network 70 sendsRRLP Measure Position Request message 120 with the network accuracy setto represent this low accuracy value (NW Accuracy). For example, thenetwork 70 may temporarily overwrite the standard network accuracy withthe low accuracy value for this MS 10.

On the other hand, if the accuracy is set by the MS 10, the network 70may send an RRLP Measure Position Request message 120 with the networkaccuracy set to represent a standard network accuracy. The MS 10overwrites or ignores the received network accuracy and uses a valuerepresenting a low accuracy instead. The MS 10 uses the network responsetime (NW Response Time) for both its internal countdown timer and itsresponse time timer (i.e., Act_timer=NW Response Time and Act_RT=NWResponse Time, respectively). At time f, once the response time timer iszero (elapse time in the example is 36 seconds), the MS 10 prepares andsends an RRLP Measure Position Response message 122.

This scenario has several advantages. Since the MS 10 started the GPSengine early (at time a) and has used a maximum possible duration oftime in determining a position fix while minimizing battery power loss,and has produced an enhanced position fix. Since the RRLP MeasurePosition Request message 120 is short (because it contains no AssistanceData), the likelihood that the message 120 will be preempted is lowered.Since the network response time is low (e.g., 4 seconds), the chance ofthe final RRLP session being aborted with another RR messages islowered. If a lowered accuracy value (e.g., Act_Accuracy=245.5 meters)is substituted for the standard network accuracy (e.g., NW Accuracy=51.2meters), the chance of the final RRLP session being aborted with anotherRR messages is lowered even further.

FIG. 19 shows yet another embodiment of call flow processing for anemergency services (ES) call. In this scenario, a first position requestmessage 120 (with or without Assistance Data) is communicated just afterthe final RRLP Assistance Data message 142. If this RRLP session isinterrupted, the network 70 delays sending a rebid position requestmessage 120A (a message without Assistance Data) until a predeterminedtime based on when the position is needed. Otherwise, the events andmessage flow from time a to time f are identical to those describedabove with reference to FIG. 17 and a description will not be repeated.

The sequence diverges from FIG. 17, at time g, where an extra RR message130 causes the current RRLP session to abort. Equivalently, the RRLPMeasure Position Request message 120 may have been preempted internallyin the network's outgoing queue (for example, because the RRLP MeasurePosition Request message 120 is long since it contains Assistance Data).In either case, the MS 10 does not have a currently open RRLP session oran instruction to reply with a position.

The network 70 delays sending a rebid message 120A until a time computedto give the MS 10 just enough time to reply with a position fix suchthat the position fix is received just in time for the network 70 toreport it. Based on an earlier RRLP session being aborted or preempted,the network 70 may determine to switch from a first mode to a secondmode. In the first mode, the network 70 sends a rebid based on theprematurely halted RRLP session and sends a rebid position requestmessage immediately as is known. That is, the network 70 bases thetiming of the next position request message on a past event, namelycompletion of the extra RR message and the need to re-send the positionrequest message a quickly as possible.

In this second mode, the network 70 does not send a rebid positionrequest message immediately. Instead, the network 70 advantageouslywaits for a duration of time based on when the position response isneeded. That is, rather than basing timing of the rebid position requestmessage on a past event, the transmission is based on a future event.For example, the timing of the next position request is based on whenthe position fix is needed (e.g., based on the remaining NW ResponseTime).

The timing of when the RRLP Measure Position Request message 120 istransmitted may be based on a predetermined time before the time thatthe position fix is needed in the network 70. In the example shown, apredetermined time is set to 8 seconds (NW Response Time=3) before theposition information is needed by the network 70. Other predeterminetimes may be used, for example, based on empirical data of variousmobile stations other predetermined times may be used (e.g., a NWResponse Time may be set to 1, 2, 4, 8 or 16 seconds). The network 70may set a timer or schedule the measurement request message so that themessage is transmitted at this future time.

At time h (t=32), the network 70 terminates the delay and transmits therebid RRPL Measure Position Request message 120A. As indicated, themessage contains no Assistance Data. Alternatively, the delay in sendingthe rebid RRPL Measure Position Request message 120A could be slightlyshorted, the response time (NW Response Time) could be slightlyincreased and the message 120A could contain some Assistance Data. Also,the accuracy parameter used by the MS 10 may be set to a largeuncertainty value (e.g., 245.5 meters) either by the MS 10 overwritingthe standard network value or by the network 70 as a temporaryuncertainty value. The MS 10 resets its activity timer to the networkprovided response time (Act_timer=NW Response Time).

In this example, the mobile subscriber's activity timer was set toexpire in 4 seconds (Act_timer=4 seconds) but this timer is reset basedon the received time (change Act_timer=NW Response Time=8 seconds). TheMS 10 may set its response time to the network provided response time(Act_RT=NW Response Time=8 seconds). At time i (t=36), the MS 10 reportsthe determined position with an RRLP Measure Position Response message122 then shuts down the GPS engine.

FIG. 20 shows a scenario where the network 70 transmits a just-in-timemeasurement request message but an earlier rebid of an Assistance Datamessage causes the MS 10 to use a network provided accuracy. Events andmessages at times a through d are identical to those of FIG. 19. At timee, the session is aborted with an extra RR message 144. Similarly, anetwork could have preempted the transition of messages 144. At times fand g, the Assistance Data is sent as a rebid RRLP Assistance Datamessage 144A and is acknowledged with an RRLP Assistance Data Ackmessage 146. The rebid message may be a rebid of the first AssistanceData message (not shown), the second Assistance Data message (as shown)or any other of a segmented sequence of Assistance Data messages (notshown).

At time h (t=20), the network 70 sends an RRLP Measure Position Requestmessage 120 for just in time receipt of a measurement report message asdescribed above. The MS 10 may set its activity timer to the networkprovided response time (Act_timer=NW Response Time=16 seconds), may setits response timer to the network provided response time (Act_RT=NWResponse Time=16 seconds), and may set its accuracy to the networkprovided accuracy (Act_Accuracy=NW Accuracy=51.2 meters).

In the previous examples, the MS 10 normally uses an accuracy value thatis a temporary value. This temporary value is a different value that iseither larger or smaller than the standard network accuracy. In thisexample, the standard network accuracy is used as an exception to usingthe different value. Finally, at time i (t=36), the MS 10 reports thedetermined measurement in an RRLP Measure Position Response messages122.

In some cases, the network 70 may detect the occurrence of a rebid (dueto an abortion or a preemption). In this case, the network 70 modifiesthe network provided accuracy from the temporary value to the standardnetwork accuracy. Alternatively, the MS 10 may detect the occurrence ofa rebid Assistance Data message (due to an abortion) and based on thisevent, the MS modifies its accuracy from the value. Alternatively, theMS may determine that the received measurement request message isdelayed base on a measured duration of time from the previous RRLPmessage.

FIG. 21 shows a flow chart relating to modifying an accuracy parameterfrom the standard network accuracy as described in reference to theprevious four figures. At 700, after the MS 10 has received an RRLPMeasure Position Request message 120, a determination is made whetherthe message 120 was sent and received on time. This determination may bedone by the MS 10 or by the network 70 based on time (e.g., someexpected time of communication), based on abortions or based onpreemptions as described above. If the RRLP Measure Position Requestmessage 120 is on time, processing continues at step 710.

At step 710, the MS 10 uses a higher than normal accuracy (e.g., 0meters) for maximal accuracy or a selected small value less than thestandard network accuracy (e.g. a value between 1 and 10 meters or avalue between 0 meters and the standard network accuracy value) for amore accurate response.

If the RRLP Measure Position Request message 120 is delayed, theaccuracy may be set to the standard network accuracy (not shown).Alternatively, if the RRLP Measure Position Request message 120 isdelayed, processing continues at step 720. Another test may be performedat step 720 to determine if the message 120 is slightly delayed or verylate. For example, an RRLP Measure Position Request message 120 may bedetermined to be slightly delayed if a rebid of an Assistance Datamessage was made. The RRLP Measure Position Request message 120 may bedetermined to be very late if a rebid of a previous RRLP MeasurePosition Request message was made. Alternatively, a RRLP MeasurePosition Request message 120 may be determined to be slightly delayed ifit is communicated later than a first predetermined time (e.g., 24second) but before a second predetermined time (e.g., 36 second). TheRRLP Measure Position Request message 120 may be determined to be verylate if communicated later than the second predetermined time. At step730, the MS 10 uses a standard network accuracy (i.e., NW Accuracy). Atstep 740, the MS 10 uses a lower accuracy value (e.g., 100, 200 or 250meters) to speed up its position response.

FIG. 22 shows a message flow diagram for a value added service (VAS), inaccordance with embodiments of the present invention. For a VAS, the MS10 does not need to use the full amount of NW Response Time.

At time a (t=0), the network 70 determines a VAS has been initiated. Inresponse, it sends an RRLP Assistance Data message 140. The MS 10 onreceipt of the RRLP Assistance Data message 140, starts its GPS engineand sets its activity timer to a predetermined value (a larger valuethan is used in the case of an ES call, e.g., Act_timer=45 seconds).Also in response to receipt of the RRLP Assistance Data message 140, theMS 10 sends, at time b, an RRLP Assistance Data Ack message 142. Attimes c and d, additional segments of Assistance Data may becommunicated and acknowledged with additional pairs of RRLP AssistanceData messages 144 and RRLP Assistance Data Ack messages 146.

At time e (t=20, Act_timer=25), the network 70 prepares an RRLP MeasurePosition Request message with a standard network time (e.g., NW ResponseTime=16 seconds) and a standard network accuracy value (e.g., NWAccuracy=51.2 meters). The network 70 sends and the MS 10 receives theRRLP Measure Position Request message 120. Unlike an ES call, the MS 10does not discard any network provided parameters. The MS 10 sets itsactivity timer, active response timer and activity accuracy parametersto network provided values (i.e., Act_timer=NW Response Time, Act_RT=NWResponse Time, and Act_Accuracy=NW Accuracy, respectively).

At time f (t=34, Act_timer=2), the MS 10 sends its determined positionin an RRLP Measure Position Response message 122 to the network 70. Inthis case, the MS sent the determined fix before the expiration of thenetwork response time due to position uncertainty being less than therequired network accuracy. Finally, in response to reporting thedetermined fix, the MS 10 shuts down the GPS engine.

It should be understood that the invention can be practiced withmodification and alteration within the spirit and scope of the appendedclaims. The description is not intended to be exhaustive or to limit theinvention to the precise form disclosed. It should be understood thatthe invention can be practiced with modification and alteration.

What is claimed is:
 1. A method comprising: initiating by a wirelesscommunication device an emergency services call; and starting by thewireless communication device a Global Positioning System (GPS) engineafter initiating the emergency services call and before a (RadioResource Location Procedure) RRLP assistance data message or an RRLPmeasure position request message are received by the wirelesscommunication device since initiating the emergency services call. 2.The method of claim 1, further comprising: receiving by the wirelesscommunication device an RRLP measure position request; and sending bythe wireless communication device an RRLP measure position response inresponse to the received RRLP measure position request, the RRLP measureposition response comprising a position determined by the wirelesscommunication device.
 3. A non-transitory computer readable medium thatwhen executed by at least one processor performs a method comprising:initiating by a wireless communication device an emergency servicescall; and starting by the wireless communication device a GlobalPositioning System (GPS) engine after initiating the emergency servicescall and before a (Radio Resource Location Procedure) RRLP assistancedata message or an RRLP measure position request message are received bythe wireless communication device since initiating the emergencyservices call.
 4. The non-transitory computer readable medium of claim3, the method further comprising: receiving by the wirelesscommunication device an RRLP measure position request; and sending bythe wireless communication device an RRLP measure position response inresponse to the received RRLP measure position request, the RRLP measureposition response comprising a position determined by the wirelesscommunication device.
 5. A method comprising: initiating by a wirelesscommunication device an emergency services call; running by the wirelesscommunication device a Global Positioning System (GPS) engine whenreceiving a Radio Resource Location Procedure (RRLP) measure positionrequest during an RRLP session; and continuing by the wirelesscommunication device to run the GPS engine upon receiving an extra RadioResources message.
 6. The method of claim 5, further comprising:receiving by the wireless communication device an RRLP measure positionrequest; and sending by the wireless communication device an RRLPmeasure position response in response to the received RRLP measureposition request, the RRLP measure position response comprising aposition determined by the wireless communication device.
 7. Anon-transitory computer readable medium that when executed by at leastone processor performs a method comprising: initiating by a wirelesscommunication device an emergency services call; running by the wirelesscommunication device a Global Positioning System (GPS) engine whenreceiving a Radio Resource Location Procedure (RRLP) measure positionrequest during an RRLP session; and continuing by the wirelesscommunication device to run the GPS engine upon receiving an extra RadioResources message.
 8. The non-transitory computer readable medium ofclaim 7, the method further comprising: receiving by the wirelesscommunication device an RRLP measure position request; and sending bythe wireless communication device an RRLP measure position response inresponse to the received RRLP measure position request, the RRLP measureposition response comprising a position determined by the wirelesscommunication device.
 9. A wireless communication device comprising: aGlobal Positioning System (GPS) engine; and a processor configured tocause the wireless communication device to initiate an emergencyservices call; and start the GPS engine after initiating the emergencyservices call and before a (Radio Resource Location Procedure) RRLPassistance data message or an RRLP measure position request message arereceived by the wireless communication device since initiating theemergency services call.
 10. The wireless communication device of claim1, the processor further configured to cause the wireless communicationdevice to: receive an RRLP measure position request; and send an RRLPmeasure position response in response to the received RRLP measureposition request, the RRLP measure position response comprising aposition determined by the wireless communication device.
 11. A wirelesscommunication device comprising: a means for initiating an emergencyservices call by the wireless communication device; and a means fordetermining position location, the means for determining positionlocation to start a Global Positioning System (GPS) engine in thewireless communication device after the means for initiating anemergency services call initiated an emergency services call, and beforea (Radio Resource Location Procedure) RRLP assistance data message or anRRLP measure position request message are received by the wirelesscommunication device since initiating the emergency services call. 12.The wireless communication device of claim 1, further comprising: ameans for receiving, the means for receiving to receive by the wirelesscommunication device an RRLP measure position request; and a means forsending, the means for sending to send by the wireless communicationdevice an RRLP measure position response in response to the receivedRRLP measure position request, the RRLP measure position responsecomprising a position determined by the wireless communication device.13. A wireless communication device comprising: a Global PositioningSystem (GPS) engine; and a processor configured to cause the wirelesscommunication device to initiate an emergency services call; run the GPSengine when receiving a Radio Resource Location Procedure (RRLP) measureposition request during an RRLP session; and continue to run the GPSengine upon the wireless communication device receiving an extra RadioResources message.
 14. The wireless communication device of claim 5, theprocessor further configured to cause the wireless communication deviceto: receive an RRLP measure position request; and send an RRLP measureposition response in response to the received RRLP measure positionrequest, the RRLP measure position response comprising a positiondetermined by the wireless communication device.
 15. A wirelesscommunication device comprising: a means for initiating an emergencyservices call by the wireless communication device; a means fordetermining position location, the means for determining positionlocation to run a Global Positioning System (GPS) engine when receivinga Radio Resource Location Procedure (RRLP) measure position requestduring an RRLP session, and continuing to run the GPS engine upon thewireless communication device receiving an extra Radio Resourcesmessage.
 16. The wireless communication device of claim 5, furthercomprising: a means for receiving, the means for receiving to receive anRRLP measure position request; and a means for sending, the means forsending to send an RRLP measure position response in response to thereceived RRLP measure position request, the RRLP measure positionresponse comprising a position determined by the wireless communicationdevice.